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Itation combined with mass spectrometry and western blot analysis. The results

Itation combined with mass spectrometry and western blot analysis. The results provide strong evidence showing that ASPM plays a critical role in meiotic spindle assembly and meiotic progression.Results JSI-124 expression and Subcellular Localization of ASPM During Mouse Oocyte Meiotic MaturationTo investigate the role of ASPM during mouse oocyte meiotic maturation, we examined its expression and subcellular localization. An analysis of ASPM expression in mouse oocytes duringMorphological and Functional Study of ASPM Genemeiosis by western blot revealed four bands, corresponding to 364, 212, 130, and 70 kDa,each with similar expression levels among different stages (GV, GVBD, MI, MII) (Figure 1A). Therefore, ASPM was expressed in oocytes from the GV to MII stages. To examine the subcellular localization of ASPM, we performed immunofluorescence staining on oocytes at different stages of 23727046 maturation and also on mouse KS-176 supplier embryonic fibroblasts (MEFs). At the GV stage, ASPM was distributed evenly in the cytoplasm. At GVBD, when chromatin was condensing and microtubules were beginning to polymerize, ASPM congregated around the chromatin and colocalized completely with the microtubules. When oocytes progressed to pro-MI and MI, ASPM was concentrated at the total spindle apparatus; for MIIarrested oocytes, ASPM was concentrated at the spindle and the polar body (Figure 1B). Throughout meiosis, Ac-tubulin coimmunostained with ASPM, suggesting that ASPM might play a role in spindle organization. However, in metaphase and telophase somatic MEFs, ASPM localized to the spindle poles (Figure 1C), distinct from its localization in the oocytes.Localization of ASPM in Mouse Oocytes Treated with Spindle-Perturbing AgentsTo clarify the correlation between ASPM and microtubules, we treated MI oocytes with spindle-perturbing drugs (nocodazole and taxol). First, we treated the MI oocytes for 5, 10 and 15 min with the microtubule-depolymerizing agent nocodazole. We found that the microtubules were gradually disassembled with an increase in treatment time, and no intact spindles were observed in the oocytes after 15 min; ASPM remained colocalized with Ac-tubulin during the entire process (Figure 2A). Next, the MI oocytes were treated with the microtubulestabilizing reagent taxol (10 mM) for 45 min. After treatment, the microtubule fibers in taxol-treated oocytes were excessively polymerized, and numerous asters were observed in the cytoplasm. Again, ASPM remained colocalized with Ac-tubulin (Figure 2B).control, respectively. In contrast, in ASPM morpholino-injected oocytes, 45.28 and 47.80 of oocytes exhibited abnormal meiotic MI and MII spindle assembly, respectively (Table 2). There were significant differences between the morpholino control and the ASPM morpholino-injected group (P,0.05). These results indicate that ASPM is required for meiotic spindle assembly during both meiotic divisions. To quantitatively compare the behavior of the spindle in control oocytes and in ASPM morpholino-injected oocytes, we measured the spindle length (S), the distance from the spindle pole to the closer cortex (D1), and the distance from the other spindle pole to the further cortex (D2) at the end of culture, as previously described [23] (Figure 5A). Both the control and morpholinoinjected control oocytes had similar S values in MI-stage oocytes (Control = 24.9162.70 mm, M-control = 24.9962.99 mm, average 6 STDEV). However, in the oocytes in the ASPM morpholinoinjected group, S was s.Itation combined with mass spectrometry and western blot analysis. The results provide strong evidence showing that ASPM plays a critical role in meiotic spindle assembly and meiotic progression.Results Expression and Subcellular Localization of ASPM During Mouse Oocyte Meiotic MaturationTo investigate the role of ASPM during mouse oocyte meiotic maturation, we examined its expression and subcellular localization. An analysis of ASPM expression in mouse oocytes duringMorphological and Functional Study of ASPM Genemeiosis by western blot revealed four bands, corresponding to 364, 212, 130, and 70 kDa,each with similar expression levels among different stages (GV, GVBD, MI, MII) (Figure 1A). Therefore, ASPM was expressed in oocytes from the GV to MII stages. To examine the subcellular localization of ASPM, we performed immunofluorescence staining on oocytes at different stages of 23727046 maturation and also on mouse embryonic fibroblasts (MEFs). At the GV stage, ASPM was distributed evenly in the cytoplasm. At GVBD, when chromatin was condensing and microtubules were beginning to polymerize, ASPM congregated around the chromatin and colocalized completely with the microtubules. When oocytes progressed to pro-MI and MI, ASPM was concentrated at the total spindle apparatus; for MIIarrested oocytes, ASPM was concentrated at the spindle and the polar body (Figure 1B). Throughout meiosis, Ac-tubulin coimmunostained with ASPM, suggesting that ASPM might play a role in spindle organization. However, in metaphase and telophase somatic MEFs, ASPM localized to the spindle poles (Figure 1C), distinct from its localization in the oocytes.Localization of ASPM in Mouse Oocytes Treated with Spindle-Perturbing AgentsTo clarify the correlation between ASPM and microtubules, we treated MI oocytes with spindle-perturbing drugs (nocodazole and taxol). First, we treated the MI oocytes for 5, 10 and 15 min with the microtubule-depolymerizing agent nocodazole. We found that the microtubules were gradually disassembled with an increase in treatment time, and no intact spindles were observed in the oocytes after 15 min; ASPM remained colocalized with Ac-tubulin during the entire process (Figure 2A). Next, the MI oocytes were treated with the microtubulestabilizing reagent taxol (10 mM) for 45 min. After treatment, the microtubule fibers in taxol-treated oocytes were excessively polymerized, and numerous asters were observed in the cytoplasm. Again, ASPM remained colocalized with Ac-tubulin (Figure 2B).control, respectively. In contrast, in ASPM morpholino-injected oocytes, 45.28 and 47.80 of oocytes exhibited abnormal meiotic MI and MII spindle assembly, respectively (Table 2). There were significant differences between the morpholino control and the ASPM morpholino-injected group (P,0.05). These results indicate that ASPM is required for meiotic spindle assembly during both meiotic divisions. To quantitatively compare the behavior of the spindle in control oocytes and in ASPM morpholino-injected oocytes, we measured the spindle length (S), the distance from the spindle pole to the closer cortex (D1), and the distance from the other spindle pole to the further cortex (D2) at the end of culture, as previously described [23] (Figure 5A). Both the control and morpholinoinjected control oocytes had similar S values in MI-stage oocytes (Control = 24.9162.70 mm, M-control = 24.9962.99 mm, average 6 STDEV). However, in the oocytes in the ASPM morpholinoinjected group, S was s.